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Co-Infections with Orthomarburgviruses, Paramyxoviruses, and Orthonairoviruses in Egyptian Rousette Bats, Uganda and Sierra Leone
, Amy J. Schuh, Tara K. Sealy, Immah Conteh, Gloria G. Akurut, Alusine H. Koroma, Kilama Kamugisha, James C. Graziano, Emmanuel Saidu, Doris F. Bangura, Emmanuel S. Kamanda, Ibrahim A. Bakarr, Jonathan Johnny, Eric M. Enyel, Jonathan A. Musa, Augustus Osborne, Ibrahim K. Foday, Camilla Bangura, Christian Sumaila, Samuel M.T. Williams, George M. Fefegula, Patrick Atimnedi, Aiah Lebbie, and Jonathan S. Towner
Author affiliation: Author affiliations: Centers for Disease Control and Prevention, Atlanta, Georgia, USA (B.R. Amman, A.J. Schuh, T.K. Sealy, J.C. Graziano, J.S. Towner); Njala University, Bo, Sierra Leone (I. Conteh, A.H. Koroma, E. Saidu, D.F. Bangura, E.S. Kamanda, I.A. Bakarr, J. Johnny, J.A. Musa, A. Osborne, I.K. Foday, C. Bangura, C. Sumaila, S.M.T. Williams, G.M. Fefegula, A. Lebbie); Uganda Wildlife Authority, Kampala, Uganda (G.G. Akarut, K. Kamugisha, E.M. Enyel, P. Atimnedi); University of Sierra Leone, Freetown, Sierra Leone (A. Lebbie)
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Abstract
We report 1.3% (19/1,511) of Egyptian rousette bats (ERBs) in Uganda and Sierra Leone were co-infected with different combinations of Marburg, Sosuga, Kasokero, or Yogue viruses. To prevent infection by those viruses, we recommend avoiding ERB-populated areas, avoiding ERBs and ERB-contaminated objects, and thoroughly washing harvested fruits before consumption.
Zoonotic co-infections occur when >2 genetically distinct infectious agents are detected in a single host (1) and are common in wildlife (2–4). Compared with infection by a single pathogen, co-infections can alter host susceptibility to other agents, disease transmission dynamics, and duration of illness (4), as well as replication and shedding of infectious agents (5).
Bats belong to the second largest order of mammals (order Chiroptera), representing 20% of known mammal species. Bats are also associated with >4,100 distinct animal viruses (6). Egyptian rousette bats (ERBs; Rousettus aegyptiacus) have been well studied as vertebrate hosts for zoonotic viruses. ERBs are a known reservoir for orthomarburgviruses (family Filoviridae, genus Orthomarburgvirus), such as Marburg virus [MARV] and Ravn virus (7), a putative reservoir for Sosuga virus (SOSV; family Paramyxoviridae, genus Pararubulavirus) (8), and the only known vertebrate reservoir for Kasokero virus (KASV) in East Africa and Yogue virus (YOGV; family Nairoviridae, genus Orthonairovirus) in West Africa (9). Virus co-infections are also frequently observed in bats; many virus-positive bats in China are co-infected with >2 viruses (10). Simultaneous shedding of multiple distinct paramyxoviruses has been reported in flying fox bats (Pteropus spp.) in Australia (11). Co-infections with multiple rubulavirus-related viruses and other unclassified paramyxoviruses have been reported in ERBs in South Africa (12). Virus co-infection in bats has been described as an underappreciated phenomenon in disease ecology and surveillance data reporting (2). Here, we investigated zoonotic virus co-infections in ERBs from Uganda and Sierra Leone
During filovirus ecology research efforts in Uganda and Sierra Leone, we captured ERBs by using mist nets and harp traps (Table). We collected visceral samples, including liver, spleen, heart, lung, kidney, axillary lymph node, salivary gland, colon, and blood, for virologic testing. We tested the samples for the known zoonotic viruses SOSV, KASV (Uganda; blood samples only), and YOGV (Sierra Leone; blood samples only). We tested samples from 1,511 bats captured during November 2009–February 2022 in Uganda and Sierra Leone (Appendix Table 1) for MARV (nucleoprotein and viral protein 35 genes), SOSV (nucleoprotein, hemagglutinin, and neuraminidase genes) and KASV and YOGV (nucleoprotein genes) by quantitative reverse transcription PCR.
In ERB samples, we detected individual infections and multiple co-infections with MARV and SOSV (n = 1,132 samples from Uganda; n = 379 from Sierra Leone), KASV (n = 942 from Uganda), and YOGV (n = 275 from Sierra Leone) (Appendix Table 2). For 1,511 bats sampled in both Uganda and Sierra Leone, 6.0% (90/1,511) had detectable MARV RNA and 10.7% (162/1,511) had detectable SOSV RNA; 3.1% (29/942) of ERBs from Uganda only had detectable KASV RNA, and 0.4% (1/275) from Sierra Leone only had detectable YOGV RNA.
In Uganda and Sierra Leone, we detected 23 co-infections with >2 viruses: 10 (43.5%) co-infections in Uganda and 13 (56.5%) in Sierra Leone. Co-infections with MARV and SOSV (1.3% [19/1,511]) were most prevalent in both Uganda (0.8% [9/1,132]) and Sierra Leone (2.6% [10/379]). We did not detect MARV and KASV co-infections in Uganda; we detected only 1 (0.4%) of 275 tested samples co-infected with MARV and YOGV in Sierra Leone. We also detected co-infection with SOSV and KASV in Uganda (0.1% [1/942]) and SOSV and YOGV co-infection in Sierra Leone (0.4% [1/275]). A single ERB from Sierra Leone had detectable RNA for MARV, SOSV, and YOGV (0.4% [1/275]) (Appendix Table 2).
Among the 19 ERBs co-infected with MARV and SOSV, 9 (47.4%) were female and 10 (52.6%) male. Eight (42.1% [8/19]) of the bats were adults (forearm >89 mm length) and 11 (57.9% [11/19]) were juveniles (forearm <89 mm length).
We detected co-infections with MARV, SOSV, KASV (Uganda only), and YOGV (Sierra Leone only) in ERBs from Uganda and Sierra Leone; most bats were co-infected with MARV and SOSV and primarily at only 1 site in each country. Most MARV/SOSV co-infections in Uganda were observe in bats from the Kitaka Mine sampling during November 2012. The mine was undergoing a resurgence of MARV infections after a depopulation and repopulation event, as previously reported (13); MARV active infection rates in ERBs had more than doubled at the mine since 2007 (7). The SOSV active infection rates were also much higher at Kitaka Mine than at the undisturbed and permanent ERB colonies at Kasungwa Cave and Python Cave sites (8). It is possible that a newly formed naive ERB population occupied the recently re-opened mine, providing an excess of bats not previously exposed to MARV or SOSV.
A comparable SOSV rate of active infection was identified at Kasewe Cave in Sierra Leone. One possible explanation for high SOSV infections at Kasewe Cave could be that the ERB population there appeared to be migratory, and the cave was mostly devoid of ERBs at certain times of the year (February–April). The ERB population at Kasewe Cave might be an amalgamation of many smaller populations that return annually to the cave site to use area resources and then disperse into smaller populations to return to other, smaller roosting sites. Subsequent reoccupations by smaller ERB populations year after year at Kasewe Cave bring new, virus naive bats together in larger numbers, similar to the repopulation of Kitaka Mine, causing higher numbers of SOSV infections in the population and, subsequently, higher rates of co-infection with MARV. Moreover, the limited data collected at the Kasewe Cave suggests the site could be a maternity roost, but because of that limitation, a definitive designation cannot be made. The ratio of juveniles to adults was higher at Kasewe Cave (59.4% [221/372]) than at Kitaka Mine (41.6% [166/399]), which could also explain the high SOSV prevalence at the cave site given recent findings of an age-related bias in SOSV prevalence at Kasewe Cave (14). More surveillance will be needed to determine normal rates of SOSV infection in ERB populations across Sierra Leone.
It remains unknown why levels of active MARV infection at Kasewe Cave are not following the same repopulation patterns as those at Kitaka Mine or following the rates of SOSV in Kasewe Cave. One possibility involves timing of collection efforts, which might have missed the peak of active MARV infections. Another potential explanation could be that SOSV, and paramyxoviruses in general, is more easily transmitted within ERB populations than MARV, when considering possible SOSV recrudescence and vertical transmission has been seen for other paramyxoviruses, such as Nipah virus (Appendix reference 16). Increases in rubulavirus-like paramyxovirus transmission during female aggregation and reproduction have been identified in a population of ERBs in South Africa, which showed seasonal population fluctuations similar to those in Sierra Leone (12). The high active SOSV infection rate, in addition to the high infection risk associated with MARV co-infection of ERBs in Kasewe Cave, indicates a substantial public health risk because of public harvests of bats for food, as well as guano mining to produce crop fertilizer. SOSV and other rubula-like paramyxoviruses have been reported to be shed in both urine and feces (guano) from infected bats (12,15). Our public health recommendations to prevent human infection by ERB-borne zoonotic viruses are to avoid entering areas where ERBs are known to roost, avoid contact with ERBs, avoid objects obviously contaminated by ERBs (including guano mining within known ERB roosts), and thoroughly wash all harvested vegetable and fruit produce from those areas before consumption.
Dr. Amman is a disease ecologist in the Virus Host Ecology Unit, Viral Special Pathogens Branch, National Center for Emerging and Zoonotic Infectious Diseases, Centers for Disease Control and Prevention, Atlanta, Georgia, USA. His primary research interests focus on investigating the ecology of and relationships between emerging zoonotic viruses and their reservoirs.
Acknowledgments
We thank the Uganda Virus Research Institute and the Uganda Wildlife Authority park rangers for their assistance during this work, the Sierra Leone government for permission to conduct this work, the Sierra Leone district and community stakeholders for support and for allowing us to perform sampling in their districts and community, and the residents and community leaders of both Tailu Village (Kailahun District) and Kasewe (Moyamba District) for their support during the field work.
All animal work was approved by the Centers for Disease Control and Prevention’s Institutional Animal Care and Use Committee (protocol no. 3063AMMBATX-A2) and had permissions from the governments of Sierra Leone and Uganda. All personnel wore appropriate personal protective equipment, including disposable gowns or Tyvek coveralls, double latex gloves or bite resistant gloves (if necessary), face shields, and respiratory protection, when handling bats and bat samples.
All data supporting the findings of this study are available within the article or from the authors upon request.
This work was funded by the US Defense Threat Reduction Agency (grant no. HDTRA1033036) and core funding from the Centers for Disease Control and Prevention.
Contributions: B.R.A, A.J.S., T.K.S., and J.S.T. conceptualized the research. B.R.A, A.J.S., T.K.S, I.C., G.G.A., A.H.K., J.C.G., K.K., and I.K.F. performed the formal analysis. B.R.A., A.J.S., T.K.S., G.G.A., K.K., J.C.G., E.S., D.F.B., E.K., I.A.B., J.J., E.M.E., J.A.M., A.O., C.B., C.S., S.M.T.W., G.M.F., A.L., P.A., and J.S.T. conducted the investigations. B.R.A, A.L., P.A., and J.S.T. were responsible for logistics. B.R.A, A.J.S., and T.K.S. determined methodology. B.R.A., A.J.S., T.K.S., I.C., G.G.A., A.H.K., K.K., J.C.G., E.S., D.F.B., E.K., I.A.B., J.J., E.M.E., J.A.M., A.O., I.K.F.; C.B., C.S., S.M.T.W., G.M.F., A.L., P.A., and J.S.T. performed data collection and curation. B.R.A., A.J.S., and J.S.T. wrote and prepared the original manuscript draft. B.R.A., A.J.S., A.L., and J.S.T. reviewed and edited the manuscript. All authors have read and agreed to the published version of this manuscript.
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Suggested citation for this article: Amman BR, Schuh AJ, Sealy TK, Conteh I, Akurut GG, Koroma AH, et al. Co-infections with orthomarburgviruses, paramyxoviruses, and orthonairoviruses in Egyptian rousette bats, Uganda and Sierra Leone. Emerg Infect Dis. 2025 May [date cited]. https://doi.org/10.3201/eid3105.241669
Original Publication Date: April 14, 2025
Table of Contents – Volume 31, Number 5—May 2025
